KR930008182B1 - Motion signal detecting circuit - Google Patents

Abstract

The circuit has a frequency unfolding circuit for unfolding a luminance signal of a high frequency component included in the luminance signal of a low frequency component into an original frequency band. It includes a prefilter (10) for eliminating the folding carrier and sidebands included in the video signal unfolded by the frequency unfolding circuit. A first comb filter (60) filters the output of the prefilter to detect a motion signal, and an error compensation circuit compensates the errors included in the motion signal output from the comb filter. The error compensation circuit comprises a second comb filter (61) and logically operates the outputs of the first and second comb filters.

Description

Copper signal detection circuit

1 is a block diagram of a dynamic signal detection circuit of an embodiment according to the present invention.

* Explanation of symbols for main parts of the drawings

10: prefilter 20, 21: first and second frame delay

30, 31: first and second subtractors 40, 41: first and second signal spreaders

50: control switch 60, 61: first and second comb filter means

70, 71: 1st, 2nd absolute stroke 80, 81: 1st, 2nd threshold detection part

The present invention relates to a system for smoothing or spreading a transition between regions of an image transmitted by a TV signal processed by the first method and the second method. Particularly, the present invention relates to a dynamic signal representing movement of an image from an unfolded image signal. It relates to a circuit for detecting.

The processing of standard TV signals, such as NTSC or PAL signals that represent an image, changes frequently to adapt to the signal's surroundings. This adaptive processing results in areas of certain images processed in one way and other adjacent areas processed in a different way. If the difference in processing is perceived by the viewer or the transition between the differently processed areas and areas is recognized, the quality of the image is degraded.

For example, a frame comb filter is used when separating the chromaticity and luminance components from a composite video signal. The chromaticity and luminance components may be completely separated as long as there is no change in the image signal at a frame time interval in the image. If the video signal changes at the frame time interval, some color information appears on the separated luminance component and some brightness information appears on the chroma component.

Line comb filters also separate the luminance and chroma components from the composite video signal and do not generate severely degraded component signals where there is image motion. However, the line comb filter reduces the vertical resolution of the reproduced image as compared to the frame comb filter. In addition, at the point where the vertical transition occurs, chromaticity information introduced to the luminance component, in which the image processed by the line comb filter generates an image artifact known as a hanging dot; The quality is degraded due to the luminance information introduced in the chromaticity component, which produces false chromaticities in the vicinity of the transition.

The TV signal is adaptively processed by detecting the presence or absence of image movement. A frame comb filter is used in an area where the image is stopped, and a line comb filter is used in an area where the image is changed.

Another example of such adaptive processing is an adaptive double-scanned non-interlaced scan converter. In such a converter, interstitial lines appear between the lines of the current field. However, if there is a change in the image that causes noticeable artifacts, such as jagged contours, the lines between the scan lines are lines from the preceding field. The lines between the scan lines can also be interpolated from the lines in the current field, but the vertical resolution falls and line flicker occurs. In areas where changes in the image are detected, lines between interpolated scan lines appear inside the field, and lines between field-delayed scan lines appear in different ways.

Another example is an adaptive peaking circuit, where areas with relatively high noise are treated with a relatively low peaking factor, and areas with relatively low noise are relatively high. It is treated as a picking factor.

In all the above examples, the processing of the TV signal changes in response to the value of the estimated parameter of the picture. The above parameter is a shift in the situation of luminance / chromatic separation and double scan sequential conversion, and is a level of relative noise in the situation of peaking. The apparent boundary between the differently processed areas and the areas where the parameter exists and the areas where the parameter does not exist is an undesirable artifact introduced by the adaptive processing scheme.

In August 1990, Samsung Electronics Co., Ltd. recorded a full-bandwidth TV signal on a recording medium with limited bandwidth by superimposing high-frequency components on low-frequency components in the mid-frequency spectrum. Patent Application No. 07/569029. According to US application Ser. No. 07/569029, the copper signal representing the movement of the image is recorded together with the luminance and chroma signals. The same signal is used to control the transition between regions of the luminance signal of the full bandwidth which is unfolded in the original frequency band during reproduction. When the high frequency component of the luminance component is superimposed on the low frequency component during recording, it is amplitude-modulated by the overlapping carrier to be combined with the low frequency component so that the superimposed luminance signal has a phase difference of 180 ° between frames, scan lines, and pixels.

Therefore, during reproduction, the high frequency components included in the low frequency components of the superimposed luminance signals are demodulated by the spread carriers having the same phase and frequency as the superimposed carriers. They are not completely removed and remain. The luminance signal spread by the overlapping carriers remaining in the unfolded luminance signal and the corresponding side waves has a phase difference of 180 ° between frames due to the overlapping carrier. For this reason, the conventional motion signal detection circuit which detects the level difference between pixels between frames as a motion signal representing the movement of the image cannot detect the exact motion signal from the unfolded luminance signal due to the phase change between the frames. According to the invention disclosed in Korean Patent Application No. "90-18737", which was filed in Korea by Koh Jung-wan on October 31, 1990, the sidebands of the superimposed carrier and the unfolded luminance signal included in the unfolded luminance signal are applied to the prefilter. By erasing. Then, the spread luminance signal from which the sidebands of the overlapping carrier and the spread luminance signal are erased is filtered by a comb filter to detect the same signal. However, the prefilter for removing sidebands of superimposed carriers and unfolded luminance signals can completely remove sidebands of superimposed carriers and unfolded luminance signals contained in the vertically and horizontally oriented luminance signal components. The sidebands of the superimposed carrier and the unfolded luminance signal included in the luminance signal component in the diagonal (time axis) direction with less correlation cannot be completely removed.

As a result, the dynamic signal, which is the difference between the frames detected by the comb filter, has a phase difference of 180 ° between the frames due to the overlapping carriers and sidebands remaining in the time axis signal component among the unfolded luminance signals. As a result, it cannot have an accurate value for the diagonal direction.

Accordingly, an object of the present invention is to provide a moving signal detection circuit capable of detecting an accurate moving signal that can indicate movement of an image for each part of a screen from an unfolded video signal.

In order to achieve the above object, the present invention provides an input terminal for introducing an unfolded video signal; Harmonic removing means for removing superimposed carriers and sidebands of the spread video signal; First comb filter means for filtering the output of said harmonic removing means and detecting a dynamic signal that is a difference of the unfolded luminance signal; And error eliminating means for eliminating errors included in the copper signal detected by the comb filter means.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of an embodiment of a motion signal detection signal according to the present invention. In FIG. 1, the input terminal 5 is connected to a frequency spreading circuit (not shown) for introducing an unfolded luminance signal, and the input terminal 5 is connected to the input terminal of the prefilter 10. In FIG. . The output terminal of the prefilter 10 is coupled to an input terminal of the first frame delay unit 20, a first input terminal of the first subtractor 30, and an input terminal of the second subtractor 31. The output terminal of the first frame delay unit 20 is coupled to the input terminal of the second frame delay unit 21 and the second input terminal of the first subtractor 30. The output terminal of the second frame delay unit 21 is connected to the second input terminal of the second subtractor 31. The output terminal of the first subtractor 30 is connected to the input terminal of the control switch 50. The output terminal of the second subtractor 31 is connected to the input terminal of the first absolute gear 70. The output terminal of the first absolute stroke 70 is connected to the input terminal of the first threshold detection unit 80. The output terminal of the first threshold detection unit 80 is connected to the input terminal of the first signal spreader 40. The output terminal of the first signal spreader 40 is coupled to the control terminal of the control switch 50.

The output terminal of the control switch 50 is connected to the input terminal of the second absolute tooth 71. The output terminal of the second absolute stroke 71 is coupled to the input terminal of the second threshold detection unit 81. The output terminal of the second threshold detector 81 is connected to the input terminal of the second signal spreader 41. The output terminal of the second signal spreader 41 is coupled with the output terminal 15. The output terminal 15 is coupled to a control terminal of a soft switch (not shown) that mixes the spatially processed luminance signal and the temporally processed luminance signal. The part 60 consisting of the first subtractor 30 and the first frame delay unit 20 is a circuit configuration of one comb filter, and the second subtractor 30 and the first and second frame delay units 20 and 21 are used. The part 61 which consists of is also the circuit structure of one comb filter.

To explain the operation, the unfolded luminance signal supplied on the input terminal 5 includes overlapping carriers and sidebands.

The prefilter 10 filters the unfolded luminance signal flowing through the input terminal 5 to remove overlapping carriers and sidebands included in the unfolded luminance signal. The circuit configuration of the prefilter 10 is a domestic patent application serial number "No. 90" for "an improved device for erasing sidebands of overlapping carriers and spreading image signals" filed in Korea on October 31, 1990 by fixed perfection. -17610 ".

The first frame delayer 20 delays the unfolded luminance signal from which the overlapping carriers and sidebands are removed for a period of one frame and supplies the delayed luminance signal to the first subtractor 30 and the second frame delayer 21.

The second frame delay 21 further delays the output of the first frame delay 20 for one frame period.

The first subtractor 30 detects the inter-frame difference signal of the unfolded luminance signal by subtracting the output of the prefilter 10 from the output of the first frame delay unit 20.

The second subtractor 31 subtracts the output of the prefilter 10 from the output of the second frame delayer 21 to detect the difference signal between the frames of the luminance signal. The difference signal generated by the first subtractor 30 is not eliminated by the prefilter 10 but becomes a frame sum signal under the influence of the overlapping carriers remaining on the time axis of the unfolded luminance signal. Even if there is a movement of the image appears.

On the other hand, the inter-frame difference signal generated by the second subtractor 31 has the correct difference between the frames even though the overlapping carrier is included on the time axis of the unfolded luminance signal without being removed by the prefilter 10. do.

The first absolute value 70 replaces the inter-frame difference signal of the unfolded luminance signal, which is the output of the second subtractor 31 having the sign of the pastor, by the moving direction and the brightness of the video signal so as to have a positive sign only.

The first threshold detection unit 80 compares the output of the first absolute stroke 70 with a preset threshold and has a value of "1" for a signal larger than the threshold and "0" for a signal smaller than the threshold. It generates a moving signal with a value or with the opposite value.

The first signal spreader 40 diffuses the dynamic signal by the difference signal between the interframe frames of the unfolded luminance signal generated by the first threshold detector 80 in the vertical and horizontal directions to spread the spread between the spread luminance signal interval frames. Generates the same signal by the signal. The first signal spreader 40 is to be configured by the contents specified in the "control signal spreader" of the domestic patent application serial number "90-17612" filed domestically by a large number of people on October 31, 1990 Can be.

The control switch 60 transmits or blocks the output of the first subtractor 30 to the input terminal of the second absolute device 71 according to the output signal of the signal spreader 40. As a result, the control switch 50 outputs the output of the first subtracter 30 and the output of the second subtractor 31 or the signal spreader 40 to eliminate an error included in the output of the first subtractor 30. Can be seen as a logical operation. This is because when the control switch 50 has an output signal of the signal spreader 40 having a high (or low) logic state (i.e., an area in which an image is moved on the screen), the first subtractor 30 is used as the same signal. This is because the output is passed to the second absolute stroke 71.

The second absolute stroke 71 replaces the difference signal between the frames of the unfolded luminance signal having the positive and negative signs flowing through the control switch 50 so as to have only the positive sign.

The second threshold detection unit 81 has a positive (+) value larger than a preset threshold value among the output signals of the second absolute stroke 71 to remove the minute interframe noise component included in the interframe difference signal of the unfolded luminance signal. The inter-frame difference signal component of the luminance signal having the sign is detected and supplied to the second signal spreader 41.

The second signal spreader 41 spreads the inter-frame difference signal of the unfolded luminance signal having a positive sign flowing from the second threshold detector 81 in time, vertical and horizontal directions to spread the inter-frame difference of the luminance signal. The signal is supplied to the output terminal 15 as the same signal. In addition, the threshold value of the first threshold value detector 80 is set larger than the threshold value of the second threshold value detector 81. This is because the unfolded luminance signal has a phase difference of 180 ° between frames due to overlapping carriers, and therefore the noise component having a larger interframe difference signal than the interframe difference signal is included.

Further, the spreading amount of the first signal spreader 40 is set to be larger than the spreading amount of the second signal spreader 41. This is because the inter-frame difference signal is detected later than the inter-frame difference signal (that is, the detection delay), so that the actual inter-frame motion cannot be faithfully followed. In order to compensate for the detection delay, the spread amount of the inter-frame difference signal is made larger than the spread amount of the inter-frame difference signal.

As described above, according to the present invention, an error included in the difference signal between frames is removed by the difference signal between every other frames by using the unfolded luminance signal having the same phase every other frame. The difference can be detected accurately.

Claims (12)

An input terminal for introducing an unfolded video signal; Harmonic removing means for removing superimposed carriers and sidebands of the spread video signal; First comb filter means for filtering the output of said harmonic removing means and detecting a dynamic signal that is a difference of the unfolded luminance signal; And error compensating means for compensating for errors included in the copper signal detected by the comb filter means. 2. The apparatus of claim 1, further comprising: second comb filter means for error compensating means for filtering an output of said harmonic removing means to detect a second motion signal; And logical calculation means for performing a logical operation on the output of the second comb filter means with the output of the first comb filter means to remove errors included in the first copper signal. 3. The motion signal detection circuit according to claim 2, wherein the motion signal detection circuit has a difference between every other frame of the video signal on which the second motion signal is spread. 3. The logic according to claim 2, wherein the logical operation means replaces an absolute value of the absolute value of the output of the second comb filter means with only a positive sign, and compares the output of the absolute value with a preset threshold value. A first threshold detector for generating a signal in the form of a signal, and a control switch for transmitting or blocking the output of the first comb filter means in accordance with the output logic of the threshold detector. . 5. The apparatus of claim 4, wherein the logical operation means further comprises a first signal spreader connected between the first threshold detection unit and the control switch to spread the output of the first threshold detection unit in time, vertical and horizontal directions. A copper signal detection circuit, characterized in that. 2. The apparatus of claim 1, further comprising: a second absolute value for absolute substitution of the output of the error compensating means so as to have a positive sign; and a diffusion dynamic signal generated by diffusing the output of the second absolute value in time, vertical and horizontal directions. And a second signal spreader. 7. The method of claim 6, wherein an output of the second absolute stroke greater than a preset threshold is connected between the second absolute stroke and the second signal spreader to remove noise components included in the output of the second absolute stroke. And a second threshold detector for transmitting the signal to the second signal spreader. 8. The apparatus of claim 7, further comprising: second comb filter means for the error compensating means for filtering the output of the harmonic removing means to detect a second motion signal; And logical calculation means for performing a logical operation on the output of the second comb filter means with the output of the first comb filter means to remove errors included in the first copper signal. 10. The logic according to claim 8, wherein the logical operation means replaces an absolute value of the absolute value of the output of the second comb filter means with only a positive sign, and compares the output of the absolute value with a preset threshold value. A first threshold detector for generating a signal in the form of a signal, and a control switch for transmitting or blocking the output of the first comb filter means in accordance with the output logic of the threshold detector. . 10. The dynamic signal detection circuit of claim 9, wherein the threshold of the second threshold detector is set to be larger than the threshold of the first threshold detector. 10. The apparatus of claim 9, wherein the logical operation means further comprises a first signal spreader connected between the first threshold detection unit and the control switch to spread the output of the first threshold detection unit in time, vertical and horizontal directions. A copper signal detection circuit, characterized in that. 11. The dynamic signal detection circuit according to claim 10, wherein the diffusion amount of the first signal spreader is set to be larger than the diffusion amount of the second signal spreader.